Transmission



Feb. 5, 1952 F. R. MGFARLAND TRANSMISSION Filed April 5, 1946 5 Sheets-Sheet l FOREST R. MFARLAND Feb. 5, 1952 R -MCFARLAND' 2,584,965

l v TRANSMISSION Filed April 5, 194e 5 sheets-sheet 2 FOREST R. wFARLAND Feb. 5, 1952 Filed April 5, 194e F. R. MCEARLAND TRANSMISSION 5'Sheets-Sheet :5 l

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.FOREST R. MFARLAND Feb. 5, 1952 F. R. MGFARLAND TRANSMISSION 5 Sheets-Sheet 5 Filed April 5, 1946 'FoREsT R. MFARLANQ Patented Feb. 5, 1952 TRANSMISSION Forest B. McFarland, Huntington Woods, Mich.,

assignor to Packard Motor Car Company, Detroit, Mich., a corporation of Michigan Application April 5, 1946, Serial No. 650,774

27 claims. l

This invention relates to transmissions and more particularly to transmissions for motor vehicles.

One type of transmission includes planetary gearing for drivingly connecting a driven shaft with one or more drive shafts powered by an engine driven fluid coupling of the Fottinger type. Reduced drive through the gearing is generally established by braking the planetary carrier and direct drive is generally established by clutching together two parts of the gearing. There is usually a. tail shaft and forward and reverse drive mechanism is employed to drivingly lconnect the driven shaft and the tail shaft.

An object of the invention is to provide a transmission of the character referred to with a fluid coupling having two runners and gearing effective to provide variable speed ratios.

Another object of the invention is to provide a transmission of the character referred to with a fluid actuated brake device for the driven shaft that will be controlled by the shift mechanism to be effective in neutral and ineffective in forward or reverse drive positions.

Another object of the invention is to provide a transmission of the character referred to with a brake for effecting reduction drive through the gearing, the brake being controlled by engine intake manifold pressure to disengage while the engine is idling.

Another object of the invention is to provide a transmission of the character referred to with automatic means consisting of a uid system having electrically controlled valves and a driver or operator and speed responsive control means, whereby the shift will be up or down depending upon intake manifold pressure and vehicle speed, modified by two driver operative means to establish reduction drive through the gearing.

Other objects of the invention will appear from the following description taken in connection with the drawings, which form a part of this specification, and in which:

Fig. 1 is a longitudinal sectional view of a transmission embodying the invention;

Fig. 2 is a fragmentary view looking at the b0ttom of the shifter sleeve valve;

Fig. 3 is a fragmentary view of the shifter mechanism looking from the inside ofthe transmission toward the outside;

Fig. 4 is a transverse sectional view of one of the control devices taken substantially on line 4-4 of Fig. 1;

Fig. 5 is a transverse sectional view through the transmission taken substantially on line 5-5 of Fig. l and showing the forward pump.;V

Fig. 6 is a side elevation showing the transmission and associated parts;

Fig. 'I is a sectional view of one cf the control devices taken on line 1-1 of Fig. 1;

Fig. 8 is a sectional view of another control device taken on line 8-8 of Fig. 9;

Fig. 9 is a diagrammatic plan view of the vtransmission and associated controls;

a motor vehicle, the iloor board I I' and instrument panel l2 of which are illustrated in Fig. 6

The transmission is housed-in a casing comprised oi' sections I2. I3, I4 and I5. A fluid flywheel indicated generally by the numeral 34 isf-housed in a chamber formed by casing sections- I2 and I3, the transmission gearing I6 is housed in casing section I4 and forward-and reverseselector mechanism Il is housed in casing1.;section I5. The rear ends of casing sections |3,-I4 and i5 g are formed respectively with transversely extending walls I8, I9 and 20. Casing section I2 is suitably secured to the rear end of engine II and the casing sections are secured together in aligned relation by suitable fastening means.

The fluid coupling 34 is of the general Fottinger type but the major portions thereof are arranged in a novel manner. The impeller consists of sections 20 and 2I secured in axial alignment by bolts 22 and form a housing for containing fluid. Section 20 is secured to the engine crankshaft 23 which provides the drive shaft for rotating the fluid coupling. The coupling also includes two runners, the primary one of which comprises a rotor 24 and a power shaft 25 and the secondary one of which comprises a rotor 216 and power shaft 21. A one-way spring clutch 28 provides a driving connection between a sleeve 29 splined to shaft 25 and a hub v30 fixed to a skirt portion 3| of the primary rotor 24. The impeller and rotors each include a shroud ring section 32 and walls 33 connecting the shrouds with the exterior walls to form passages therebetween through which fluid circulates in a counter clockwise direction as viewed in Fig. l. The passages in the impeller section 2l open forwardly and the passages in the rotors are arranged so that fluid leaving the impeller rst passes into the primary rotor 24, from the primary rotor to the secondary i assent rotor 23 and from the secondary rotor back into the impeller section 2 I.

Drive from the runners is transmitted to driven shaft 35. which is in axial alignment with runner shafts 25 and 2i, by gearing of the planetary type and by means of which two geared reduction drives may be had through two gear trains. Gear 33 is fixed to the rear end of shaft 25, gear 31 is fixed to the rear end of shaft 21 and gear 33 is fixed to the front end of shaft 35. Gears 31, 36 and 33 mesh respectively with planet gears 39. 40 and 4| that are shown formed as a unit but they may be formed separately and secured together as a unitary structure. There may be one or more of these planet gear units and each unit is rotably mounted on a pin 42 fixed to a carrier 43. When rotation of the carrier is unrestricted it will be driven freely in a reverse direction and drive will not be transmitted therethrough to shaft 35. The low speed reduction gear train consists of gears 3l, 4l, 4i and 3l while the higher speed reduction gear train consists of gears 31, 39. 4i and 33. When the carrier 43 is held stationary drive will be transmitted through one or the other of the gear trains depending upon which of the run-- ners 24, 23 is effective. When the fluid coupling is rotating at low speed the primary runner will be effective to drive power shaft 25 and the low speed gear train associated therewith, and at some increased speed of rotation of the fluid coupling the secondary rotor will become effective so that shaft 21 will become the driver for the gear train associated therewith and shaft 2l will overrun rotor 24. Drive through either of the gear trains will be referred to as geared drive.

Tail shaft 44 is in axial alignment with telescoped shafts 25 and 21 and extends into the sleeve shaft 35. Shafts 35 and 44 are connected for forward or reverse drive by mechanism i1.

Bun gear 4l is splined on shaft 3l and is shiftable axially thereon. The tail shaft is provided with splines or teeth 43 with which internal clutch teeth 41 on the sun gear 45 are adapted to be meshed to provide a direct connection between the driven shaft and the tail shaft in order that forward drive of the vehicle may be effected. A clutch sleeve or carrier 43 is sleeved but prevented from endwise movement on sun gear 4l and has external teeth 49 formed thereon adapted to engage with intemal teeth 54 formed on an abutment member fastened by bolts 52 to wall I9 of the casing section I4. The carrier 43 supports pins l2 on which reverse idler gears 53 are ro: tatably mounted. These reverse idler gears mesh with sun gear 45 and with internal teeth on ring gear 54 that is engaged with splines 43 to rotate in unison with tail shaft 44. The clutch shifter sleeve 43 is formed with a recess 55 to receive shift fork HU, see Fig. 1l. When the clutch sleeve is shifted to the left, as viewed in Fig. 1, teeth 43 will mesh with teeth Il to hold the clutch sleeve stationary so the drive from the sun gear 4l through the planet gears 53 to ring gear 54 will rotate tail shaft 44 at a reduced speed and in a reverse direction relative to the rotation of shaft 35. When the clutch sleeve 43 is shifted to the right, as viewed in Fig. l, sun gear teeth 41 will engage with splines 43 so that shaft 44 will be rotated in the same direction and as a unit with shaft 3l.

The reaction devices 51 and 53 in casing section I4 are provided to hold the carrier 43 stationary in order to establish geared reduction drive through the planetary gearing. The device Il includes a reaction member 52 having a rim portion adapted to be engaged and held stationary by a brake band 80. The ring extension il is secured to the rear end of carrier 43 by bolts 62 and another member 63 fixed to abutment member 59 projects within the carrier extension and has cam surfaces in spaced relation therefrom. Brake rollers 64 are arranged between the inner surface of the carrier extension and the cam surfaces of the abutment ring and serve as a oneway brake device for the carrier when the brake band 60 is applied to reaction member 59. With this form of one-way brake arrangement for the carrier, drive will be transmitted from the fluid coupling through the gearing to the driven shaft 35 when the brake is applied and the coupling is the driving member, but when the tail shaft 44 is the driver then of course there will be no driving connection forwardly through the gearing from +he shaft 35 to the runners.

When the reaction device 51 is effective positive geared drive between the fluid coupling and the driven shaft 35 will be definitely established regardless of whether the fluid coupling or the driven shaft is the driver. The carrier 43 is formed with a forwardly extending shell 65 forming a reaction member against which brake band 38 is applied to hold the carrier stationary.

High speed drive through the planetary gearing is obtained by the application of a friction clutch device 61 that is housed by the extension 65 of the carrier 43 and by closure member 3l. This clutch device when applied provides part of a connection whereby carirer 42 will be .driven from the fluid coupling impeller at the same speed as the power shaft 23. The clutch device includes clutch plates 63 slidably splined alternately to carrier extension 05 and clutch hub 1l which latter is splined to sleeve shaft 1| rotatably mounted around the runner sleeve shaft 21 and extending forwardly through wall I3 into the chamber housing the fluid coupling. The forward end of this shaft 1i has a ring member 12 splined thereon and partially telescoped by ring plates 13 fixed to a hub 14 by rivets 15. This hub member 14 is secured to the shell of the impeller section 2| by bolts 16. The rivets 15 extend through segmental slots in ring member 12 so that there may be some rotative movement between the ring member 12 and the hub member 14. Coil springs 11 are disposed in registered recessed portions of the ring plates 13 and the ring member 12 to provide a limited flexible driving connection therebetween so that shock resulting from engagement of the clutch plates will be absorbed. The clutch plates 69 are normally disengaged by coil spring 13 urging pressure plate 15, as viewed in Fig. 1, to the left, and the clutch plates are engaged through means of pistons l0 slidable in chambers in the closure member 3B.

When the clutch device 61 is engaged a driving connection between impeller section 2| and carrier 43 is established thereby imparting rotation to gear 4i bodily about the axis of the carrier which tends to rotate gear 33 on driving shaft 35 therewith. At the same time the fluid coupling speed is such that the primary runner 24 will be the driver and will impart rotation through the lower speed gear train drive by shaft 25. While there is some reaction to the primary runner drive, it is overcome by fluid pressure in the coupling so the drive from the coupling to the driven shaft 35 will flow through two paths, and the joint torque thereof is transmitted to the driven shaft. The speed at which the driven shaft is rotated is substantially that at which V in the form of a brake device 8|.

this relation there can be no drive transmitted f from shaft 35 to shaft 44. In order to aid the engagement of the forward and reverse mechanism |1 when shifting into forward or reverse drive relation I provide synchronizing mechanism This device comprises brake. plates 82 engageable with member 5| by means of a pressure operated piston 83 against which springs 84 act to normally allow the plates to disengage'. The brake p1ates,springs and piston are arranged in a chamber formed by abutment member 5| and Wall I9. The plates 82 are slidably splined on the driven shaft 35 and are clamped against stationary abutment member 5|. The arrangement is such that the plates when engaged will hold the driven shaft 35 stationary while the forward and reverse mechanism I1 is in neutral position and the engine is running so that there lwill be no rotation of teetl.` 43 or teeth 41 while being shifted into engagement with teeth 59 and 46 respectively to effect forward or reverse drives.

The reaction brake devices 51 and 58, the synchronizer brake device 8| and the clutch device 61 are controlled by a fluid system in which is arranged a plurality of valve control devices, see Fig. l1. Valve device 86 controls fluid ow to one-way reaction brake device 58, valve device 81 controls fluid flow to the clutch device 61 and valve device 88 is effective to control shift down from the clutch device 61 to the two-way brake device 51. Valve device 89 controls fluid flow to the synchronized brake device 8|. and one end of the shift rail 90 for shifting clutch sleeve 48 forms a primary valve device 9| controlling flow to the valve devices 86, 81 and 88.

There are two pumps 92 and 93 in the fluid control system by means of which fluid under pressure is circulated from the bottom of casing section I4 to the various control devices under pressure suflicient to operate them. Front pump 92 consists of gears 94 and 95 housed in a chamber between wall I8 and wall 96, gear 95 being rotated by shaft 1I that is rotated directly by the impeller of the fluid coupling. This particular form of gear pump is conventional. to the pump 92 from the bottom of casing I4 through a screen 91 and passage 98 and is moved from the pump through a passage 98 to main delivery passage 99. a suitable pressure relief valve being associated with the outlet side of the pump to limit the pressure in the delivery passage 99.

Rear pump 93 is similar in construction to pump 92 and comprises gear |0| fixed to tail shaft 44 and gear |02 housed in a chamber formed by wall 20 and cover plate |03. Inlet passage |04 leads from screen 91 to pump 93 and outlet passage leads from pump 92 to the main feed passage 99 through the casing sections I5 and I4. Pressure relief valve |06 is provided in the outlet passage |05.

The main fluid feed passage 99 has two outlet branches |01 and |08, branch |07 leading to the synchronizer brake 8| and branch |08 leading to the other fluid control devices. Fluid ow to the synchronizer brake is under control of the forward and reverse gearing shifter mechanism in which shift rail 90 has a fork ||0 fixed thereto that engages in the recess 55 of sleeve 48. This shift rail is mounted in a valve and actuator Fluid is moved i 6 sleeve having a slot ||2 into which arm |I3 engages, such arm also extending through a slot ||4 in the shift rail. Arm ||3 is fixed to shaft ||5 extending outside of casing I5 and arm 56 fixed on shaft |I5 is connected by link |1 with bell crank ||8 that is rocked by rod ||9 actuated by an arm ||9 on rod |20 arranged adjacent the steering wheel column |2I and having a handle |22 for operation by the driver.

Valve sleeve is axially movable ir. bore |23, shift rail 90 is axially movable relative to valve sleeve III, and the valve end 9| is axially movable in sleeve |25 fixed to casing 4. Collar |26 is fixed to rail 90 and coil springs |21 surround the rail between the sleeve valve and the fork !I0 and between the sleeve valve and the collar |26. These springs balance to normally maintain the valve sleeve in a central position between the fork |I0 and collar |26. The valve sleeve has a peripheral groove I3I a narrow section of which is adapted to be registered `with branch passage |01 and a wider section |32 of which registers with passage leading to the synchronizer brake chamber.

When shifter arm II3 is in neutral position, valve sleeve will be in its central position to register groove section |3| with passage |01, thereby allowing ud ow to engage the synchronizer brake. Upon rocking arm ||3 fore or aft by operation of lever |22, the valve sleeve I| I will be shifted ahead of rail 90, this being possible because slot |I4 is wider than slot II2, see Fig. 3. Such shifting of the valve sleeve will shift groove |3| out of registration with passage |01 to shut off uid flow to the synchronizer brake and groove section |32 will vent passage |35 as the shifter mechanism is clutched for forward or reverse drive. Shifting of the valve sleeve ahead of the rail 90 will cause one of the springs |21 to exert a force against the fork ||0 or collar |26, depending upon the direction of shift, suicient to engage the clutch sleeve for forward or reverse drive. In the event the clutch teeth abut when the shift is made, the spring.

will be compressed and will complete the shift upon slight rotation of one of the clutch members. Detent (shown diagrammatically in Fig. 6) is arranged to engage recesses 4| in the rail under light spring pressure to retain the shift mechanism in forward, reverse or neutral.

The shift rail 90 in addition to selecting forward and reverse drive and controlling fluid flow to the synchronizer brake device also provides a primary valve for controlling flow in the iiuid system through feed passage |00 connecting passage 99 with control valve devices 86. 81 and 88. Sleeve |25 receiving the rail valve end 9| has aligned ports |36 that are shut when the rail is in neutral position. The rail has pasages |31 and |38 therethrough adapted to register with ports |36 when the rail is in forward or reverse position. Thus the fluid system'to valve devices 86, 81 and 88 is shut off by the shift rail in neutral position and is open through the shift rail when in forward or reverse positions.

Passage |08 extends across the casing section I4 through wall I9 Where it connects with passage |39, see Fig. 1l, having outlet branches |40, |4| and |42. Branch passage |40 leads to valve sleeve |43 of control device 86, branch passage |4| leads to valve sleeve |44 of control device 81 and branch passage |42 leads to valve sleeve |45 of control device 88. Passage |46 vparallels passage |39 and has branch passage |48 leading to sleeve |43, branch passage |49 leading to sleeve |44 and branch passage |50 leading to valve sleeve |45. Passage leads from valve sleeve |45 to the clutch chamber in carrier extension 68 so that pressure fluid may act against actuator 80 to engage the clutch device 61.

Valve device 86 is arranged to control brake device 58 and the position of valve |52 in sleeve |43 is under control of spring |53 and pressure in the engine fuel intake manifold |54. Cap |55 clamps diaphragm |56 to sleeve |43 and forms a chamber |51 that is connected with the intake manifold by conduit |58. The diaphragm is secured to the valve |52, and the spring |53 in chamber |51 creates a force against the diaphragm urging the valve toward the right in Fig. l1 to open position. The spring force is opposed by subatmospheric manifold pressure and the arrangement is such that subatmospheric manifold pressure is sufficient to overcome the spring and close valve |52 when permitted to function with the engine idling. Valve |59 is interposed in conduit |58 and is normally held open by spring |60 and is closed by cam |6| rotatable with throttle valve operating rod |62 that is given rotative movement from the accelerator pedal |63 by lever |64 and link |65. When the accelerator pedal is in engine idling position, the cam will permit spring |60 to open valve |59 whereby subatmospheric pressure in the intake manifold will shift diaphragm |56 to close valve |52. Upon depressing the accelerator pedal to accelerate the engine, cam |6| will shift valve |59 to close the connection with the manifold and to open chamber |51 to atmosphere through vent |66. Thus the brake control device 86 will be ineffective to hold the planetary gearing carrier, when the engine is idling and the vehicle is standing still, until the accelerator pedal is depressed from engine idling position. In order to establish drive by device 51. the shift rail 90 must be first moved to forward or reverse position and the accelerator must be depressed, such operations being in series.

The valve control device for brake 60 includes means whereby brake application occurs in two stages having different rates of speed. Valve housing sleeve |43 has a port |10 open to the valve chamber and to branch passage |40 and has another port |1| open to the chamber and branch passage |48. Actuator chamber |12 is connected with the valve chamber by passage |14, and chamber |11 is connected with the valve chamber by a passage |13. Piston valve |52 has a plurality of flanges or lands whereby port may be connected with either of the passages |13 or |14 depending upon its position and, as shown in Fig. 11, the engine is running idle and the vehicle is standing still so that valve |59 is open whereby valve |52 has been moved to its left position opening passage |40 to passage |13 and closing passage |40 to passage |14.

A compound piston and valve device is arranged in chamber |12 and forms part of the actuator means for the brake in device 58. Sleeve piston is axially movable in the chamber |12 and has a flange |16 at one end sealing off passage |14 from the chamber |11 with which passage |13 openly communicates. Sleeve piston |15 also has an internal fiange |18 and within the sleeve piston a nested piston member |19 is axially slidable. Between the planed head end of said piston member |19 and the flange |18 is arranged a coil spring |80. A stop ring |8| in piston |15 limits axial movement of piston member |19 in one direction and spring normally seats member |19 against the stop ring |8| whereby the other end of member |19 is spaced from flange |16 and such space opens to port |82 in member |15. A valve |83 is located internally of the telescoped piston members and is normally held against stop ring |84 in member |15 by spring |85 arranged within member |19. The valve |88 has limited axial movement and a radial port |88 adapted to vent fluid from chamber |11 when moved to communicate with port |82. Member |19 has a vent port |81 in its end and through which fiuid passing through valve port |86 may flow back into casing |4. Piston member |19 is fixed to one end of rod |88 and the other end of the rod engages cam lever |89, see Fig. 4, arranged to actuate arm |90 mounted on pin |9| in bracket |92 fixed to brake band 60. The other end of such brake band has a bracket |93 abutting an anchor member |94 fixed to casing I4.

The valve control device 88 in the fluid system for the two-way brake reaction device 51- includes the housing sleeve |45 in which flanged hollow valve |95, open at one end, is axially movable. Port |96 connects conduit |42 with the interior of the valve sleeve and port |91 connects conduit |50 with the interior of the valve sleeve. The fluid feed conduit |5| to the clutch device 61 is connected with the interior of the valve sleeve by port |98 and sleeve port |99 is open to passage 200 leading to the interior of casing 20| in which actuator piston 202 is axially movable. This piston is fixed to rod 203 for operating mechanism (not shown) for applying and releasing brake 66, the operating mechanism being the same as that between rod |88 and brake band 60. Valve |95 is attached tov diaphragm 204 to which armature 205 of grounded solenoid 206 is fixed and is normally opened to the clutch device by spring 204'. When valve is in the position shown in Fig. 11, vent |99 therein is open to port |99 relieving chamber 20| of fluid.

Valve device 81 comprises a valve sleeve |44 and a flanged valve 201 that is axially shiftable in the sleeve. This valve device serves to establish or shut off fluid flow bet-Ween conduits |48 and |39. Port 208 in the valve sleeve communicates with conduit |4| and port 209 in the valve sleeve communicates with conduit |49. The valve is fixed to a diaphragm 201 and to armature 208 of solenoid 209 and is normally opened by spring 205'.

The valve devices 81 and 88 are controlled by electrically energized means including the solenoids 206 and 209'. Battery 2|0 is connected with line 2| leading to solenoid 209 and a switch 2|2 is interposed in such line, the switch may also be for the engine ignition system (not shown). Line 2|3 connects line 2| with contact 2|4 at the instrument board and contact 2|4' is connected by line 2|6 with solenoid 208. Switch 2|5 is operable by the driver to engage and disengage contacts 2|4 and 2| 4' to control the electric circuit to solenoid 208.

Solenoid 209 is connected with contact 2|1 by lines 2|8 and 2|8', and a grounded switch 2 |9 fixed to accelerator pedal |63 is operable to engage or disengage the contact 2|1 to make or break the electric circuit for solenoid 208'.

Solenoid 208 is also controlled by a device 228 in which an electric circuit is controlled by means responsive to vehicle speed and fuel intake manifold y pressure. Line 2| 8 leads to contact 2|8 (see Fig. 10) of a switch having a grounded contact arm 22| movable by an actuator plunger 222 fixed to diaphragm 223 traversing chamber 224 in switch housing 25. This housing also contains a chamber 228 closed by diaphragm 221 and containing spring 228. Conduit |59' is in open communication with chamber 226 and subatmospheric pressure acts upon diaphragm 221 to move it to the right, as viewed in Fig. 10, and spring 228 .acts to move the diaphragm to the left.

Housing 225 also containsa vehicle speed responsive valve device for a fluid pressure system connecting pump 93 with the actuator plunger 222 for switch arm 22|. Passage 229 leads from pump 93 to passage 230 and passage 23| leads to the plunger actuator 222. Passage 230 connects with a circular groove 232 in thebored standard 233 and passage 23| connects with circular groove 234 in the bored standard. Sleeve shaft 235 is rotatably mounted in the bored standard and has ports 236 registering with ports 234 and ports 231 registering with groove 232. This sleeve shaft has gear 238 xed thereto and meshing with gear 239 driven by tail shaft 44. Fly- CII weights 240 are pivoted on -pins 24| fixed to the sleeve shaft and have arms carrying pins 242 extending between flanges 243 on valve member 244 that is axially movable in and carried by the sleeve shaft. Another valve member 245 projects into valve member 244 and bears against plunger 246 fixed to diaphragm 221. Member 244 of the compound valve is shifted by the governor fiyweights opposed by spring 246. Member 244 has radial fluid inletiports 241 adapted to register with groove 232 and ports 231 and member 245 has radial ports 248 adapted to register with ports 241 of the other valve member, ports 248 being open to an axial passage 249 extending through the inner end of member 245. A circular vent groove 250 extends around the bore wall of standard 233 and registers with the space 25| between the inner end of valve member 244 and flange'252 on valve member 245 that slidably engages the inner wall of sleeve shaft 235. Spring 253 exerts pressure against flange 252 to hold valve member 245 against plunger 245.

When the vehicle is standing still the rear pump 93 will not be operating and the front pump 92 is operative only while the engine'is running.

Thus, whenever the ignition switch 2|2is closed and the engine is running, the pressure fluid system will be conditioned for operating the various control devices with which it is connected.' With the engine idling and the forward and reverse mechanism in neutral the shift rail 90 will shut oii` iuid flow from conduit 99 to conduit |39. Also when the shift mechanism is in neutral sleeve valve will be in its neutral position, due to the similar force exerted against opposite ends thereof by springs |21, to register grooves sections |3| and |32 with conduits |01 and |35 whereby pressure fluid will flow to the synchronizer brake device 8| and will act against the actuator piston 83 to engage the brake plates 82 and thereby frictionally hold the shaft 35 stationary. With the shaft 35 held stationary the driver next conditions the mechanism for forward or reverse vdrive by moving the shift lever forwardly or rearwardly to register one ofthe ports |31 or |38 with passage |08 to thereby connect conduit 88 with conduit |88. lValve device 88 is normally held in open position by spring |88 to connect port |18 and passage |48 with passage |14 but with the engine idling conduitV |88 will be opened so that intake manifold sub-atmospheric pressure will overcome spring |58 and will move valve |52 to the position shown in Fig. 11 whereby there can be no flow of fluid from conduit |48 through passage |14 and consequently brake device 58 will be released from the reaction member 59 so that the carrier is free m rotate in a reverse direction carrying the planetary gears therewith. With the synchronizer brake device 8| applied. shaft 35 is `held stationary sothat when the sleeve 48 is shifted to engage teeth 48 with teeth 50 or teeth 41 with splines 48 there will be no relativerotation of such teeth to be mated and consequently the shift can be made without clashing of the clutch teeth. The transmission is now conditioned to drive as soon as brake device 58 is engaged and it isonly necessary for the driver to depress the accelerator pedal beyond throttle idling position in order to establish the low speed geared drive. As the accelerator pedal is depressed cam |6| will move valve |59 to cut off the sub-atmospheric pressure line |58 from chamber |51 and spring |53 will move valve |52 to permit flow from conduit |48 to passage |14. Prior to this shiftingof the valve |52 conduit |48 has been opened to passage |13 so. upon the spring shifting the valve, pressure iiuid is trapped in passage |13,l chamber |11, port |82 and the space between the piston ange |18 and the end of the push rod piston |19 adjacent thereto. This trapped pressure :duid opposes movement of the piston |15 and retards the engagement of the brake device 58 so that a progressively increasing effect and a soft engagement of the brake are obtained.

As the pressure behind the piston |15 increases the valve |83 is moved against the pressure of spring |85 to register port |88 with port |82 so that fluid can vent from portV |81'. Pressure iiuid flowing into chamber |12 from passage |14 will rst move valve |83 toward the right, as viewed in Fig. 11, to thereby push spring |85 against the piston |19 which will initiate movement of rod |88 to engage the brake band 60. A similar movement of valve |15 is opposed-by spring and by the trapped pressure fluid. Since valve ports |86 register with port `|82 some of the trapped pressure uid can escape through vent |81 so that the piston |15 can be moved to the right by pressure in chamber |12. Pistons |19, |83 and |15 now move to the'right until brake 58 is applied lightly. The reaction of brake 58 isA transmitted back to rod |88 and pistons |19 and |83 through lever |89 and arm |90. Piston |15 continues to move until port |82 is blocked oi by closure of the space between pistons |15 and |19.y f

Up to now only spring loads |80 and |85 and pressure on piston |83 have been applied to brake 58 which will insure against a harsh application. A harsh application is further prevented by oil pressure in chamber |12 since rapid ventingl of chamber |11 is prevented after take up of brake 58, the vent space having been closed. Slow leakage of `vent chamber 11 in clearance between piston |15 andho'using r|4 or piston |19 causes soft engagement of brake 58. kSince the brake holds abutment member 59 stationary. the one-way brake 64 will become effective to prevent reversey rotation of carrierL 43 whereupon drive will-beestablished from either one of the runner power shafts 25 or 21, depending upon which will hold selector valve 201 in the position shown in Fig. 1l whereby communication between the main feed conduit |4| and the outlet passage |49 is cut off and hence there can be no fluid flow through conduit |48 or passage |50. The dash switch 2|5 will be open so that there will be no circuit to solenoid 208 and valve |85 will be moved to the position shown in Fig. 1l

shutting off port |88 and opening port |81 to port |98 but this is immaterial because there will be no fluid fiow in conduit |48 because of valve 201 shutting off fluid flow thereto from conduit |4|. Thus the clutch device 81 will have no pressure fluid flowing thereto and it will be disengaged. Fluid flow from conduit |42 to piston chamber 20| is cut off by valve |95 and chamber 20| is open to vent |99' so that brake device 51 will not be applied. In the meantime as soon as shift rail 90 is moved to establish flow through either one of the ports |31 or |38 and the sleeve 48 has been movedl into forward or reverse drive relation, sleeve valve will first be shifted by end of arm ||3 to move port |3| out of registration with passage |01 whereby fluid flow to engage the brake is shut off and the wider groove section |32 is moved to vent passage |35 leading to the synchronizer brake. As arm ||8 is moved it will compress one of the springs |21 thus shifting rail 90 and moving yoke ||0 therewith for engaging the teeth 41 or 49 into mesh establishing forward or reverse drive position depending upon the direction of shift. In the event the teeth 41 or 49 abut, when being shifted into engagement, one or the other of the spring |21 will be compressed and will cock the sleeve valve to move the teeth into engagement with the mating teeth as soon as there is a slight rotation of the clutch sleeve or the tail shaft. With the control devices in the position just described the transmission will remain in geared drive until a vehicle speed and intake manifold pressure cause a shift to high speed drive. Spring 248' of the speed responsive device will prevent this up shift until the vehicle speed is above 12 miles per hour or thereabouts, such speed being referred to as the governed speed.

Up shift to high speed gear ratio in the planetary gearing takes place when the circuit to solenoid 209' is broken. This can be accomplished by disengaging arm 22| from contact 2|8' by means of fluid pressure flowing through conduit 229 to passage 230 and into passage 23|, when the compound valve permits such flow, whereby actuator 222 is shifted to open the switch arm 22|. The compound valve device is arranged so that as the weights 240 move out in response to increased vehicle speed they will move sleeve 244 to the left, as viewed in Fig. l0, and subatmospheric intake manifold pressure acting upon diaphragm 221 will move the valve member 245 axially in opposition to spring 228 acting against the diaphragm. The arrangement is such that this compound valve will be closed below the gcvemed speed and it may be opened at any speed above the governed speed depending upon pressure in chamber 228. Thus the valve member 245 selects the speed at which ports 248 and passage 249 will be open to ports 241 whereby fluid may flow from passage 280 to passage 28| through ports 288 in the driving shaft for the flyweights. As soon as pressure fluid passes through passage 248 it will act against flange 252 to return the valve member 245 and the guide plunger 248 to the extreme right hand position beyond that shown in Fig. 10, whereby sleeve valve 244 will have to move to a position below the governed speed before the pressure fluid will again be cut oil'. While switch 22| is held open to break the circuit to solenoid 209' valve 201 is moved to the right. as viewed in Fig. 11, to establish flow between ports 208 and 209. Solenoid 208 is deenergized so valve |95 is in the position shown in Fig. 11 and pressure fluid will flow from passage |4| to passage |48 through passages |48 and |50 and through the ports |91 and |88 in the valve sleeve |45 to passage |5| leading to the clutch device 81 to apply the same whereupon the drive will be direct from the fluid coupling member through shaft 1| and the clutch device to the carrier 48. At the same time rotor 24 and shaft 25 will be driving and these two paths of power flow will be transmitted through the planetary gearing to shaft 35 so that the tail shaft 44 will be driven at substantially the same speed as the engine drive shaft 23 except for fluid slip in the coupling. Brake device 58 can remain applied as the carrier can overrun abutment member 58. As conduit |48 is now open fluid will flow through conduit |48 and passage |1| to the interior of sleeve |48 where it will act against the large diameter flange at the end of valve |52 to hold the valve in its right hand position even though subatmospheric pressure is in conduit |58 so when the accelerator pedal is released to idling position, it cannot shift valve |52 to its left hand position as shown in Fig. il. Thus pressure fluid in the clutch feed passage is utilized to hold valve |52 in relation applying brake device 58 when the accelerator is in idling position. Thus the transmission is always conditioned to immediately go back into geared drive automatically when the clutch device 81 becomes ineffective. When the clutch device 51 is engaged valve |85 will be in the position shown in Fig. 1l cutting off fluid now through port |88 but chamber 20| will be vented by passage 200, port |88 and port |89. Switch 22| will remain open until the vehicle speed is less than the governed speed whereupon fluid pressure against the switch actuator 222 is relieved and the switch can again close and valve 201 is moved by solenoid 208' to the position shown in Fig. l1 cutting off flow to the clutch device and the brake device 58 which has been held stationary takes over the drive through the one-way brake member 84.

Provision is made for overruling the effect of the speed and vacuum device controlling switch and the driver may utilize overtravel of the accelerator pedal to complete a circuit to solenoid 209' by engaging switch 2|'8 with contact 2|1. Even though the transmission is conditioned for high speed drive this establishment of a circuit to the solenoid 208 will shift the selector valve 201 to the geared drive position as shown in Fig. l1 cutting off fluid flow from conduit |4| to conduit |49 and therefore to the clutch device 81. The transmission will now function just as it would in geared drive so long as the accelerator pedal remains in overtravel position closing the circuit to solenoid 208 through assente switch 2|9. As soon as the accelerator pedal permits switch 2| 9 to again open, which it will do when the accelerator pedal is raised to less than wide open throttle position, and when the vehicle is traveling about the governed speed, solenoid 209' will be deenergized and valve 201 will move to high speed position so that .the clutch device 61 will again take over the drive.

Another means is provided for establishing geared drive regardless of vehicle speed. Solenoid 206 is normall deenergized but the circuit therefor may be established by closing the dash switch 2|5 at the will of the driver. Energizing of solenoid 206 will move valve |95 to the left as viewed in Fig. 11 which will close fluid port |91 in the valve sleeve and will open port |98 so that fluid in conduit |5| will be -vented through the end of the valve sleeve. At the same time the valve |05 has moved to the left so that conduit |42 and port |96 are open to port |99, passage 200 and chamber 20| in which piston 202 for actuating brake rod 203 is located. Fluid can now flow to move the actuating mechanism for the two-way brake device 51 to engage the same upon the planetary carrier extension 65 so that geared drive is established through the planetary gearing and the clutch device is vented through port |98 so thatI high speed drive cannot be established. As long as switch 2|5 is closed the transmission will remain in geared drive. While the two-way brake device is effective, the one-way brake device 59 is also effective below the governed speed so in the 'event the solenoid 206 is deenergized and the vehicle is operated below the governed speed the brake device 58 will be applied and the transmission Will remain in geared drive. If the vehicle is running above the governed speed when switch 2I5 is open, then valve |95 will permit fluid flow to the clutch device 6l and high speed drive will be established.

It will be understood that various forms of the invention other than those described above may be used without departing from the spirit or scope of the invention.

What I claim is:

1. In a transmission for motor vehicles driven by an engine having a fuel intake manifold, a power shaft, a driven shaft. planetary gearing including a carrier adapted to connect said shafts in drive relation, a brake device for the carrier, a clutch device for connecting the carrier to the power shaft, a pressure fluid system adapted to operate said devices, valve means for controlling fluid flow in the system to selectively engage said brake device or said clutch device, an electrically energized means for controlling said selector valve means, passage means connecting the pressure fluid system with the electrically energized means in relation to control the pressure fluid system. a valve device in the passage means, means responsive to vehicle speed for actuating said valve device, and means responsive to pressure in the intake manifold for actuating said valve device, said valve device being opened in a variable vehicle speed range above a predetermined speed selected by varying intake manifold pressure.

2. In a transmission for motor vehicles driven by an engine having a fuel intake manifold, a power shaft, a driven shaft, planetary gearing including a carrier adapted to connect said shafts in drive relation, a brake device for the carrier, a clutch device for connecting the carrier to the power shaft, a pressure fluid system trolling said selector valve including a switch,

passage means connecting theA pressure fluid system with the switch in relation to control the pressure fluid system, a valve device in the passage means, means responsive to vehicle speed for controlling said valve device, and means responsive to pressure in the intake manifold for controlling said valve device, said valve device being opened in a variable speed range above a predetermined speed depending upon varying intake manifold pressure.

3. In a transmission for motor vehicles driven by an engine having a fuel intake manifold, a power shaft, a driven shaft, planetary gearing including a carrier adapted to connect said shafts in drive relation, a brake device for the carrier, a clutch device for connecting the carrier to the power shaft, a pressure fluid system adapted to operate said devices, valve means for controlling fluid flow in the system to selectively engage said brake device or said clutch device, an electrically energized means for controlling said selector valve including a switch. passage means connecting the pressure fluid system with the switch in relation to control the pressure fluid system, a compound valve device in the passage means, means responsive to vehicle speed for controlling one part of said valve device, and means responsive to pressure in the intake manifold for controlling another part of said valve device, said valve device being opened in a variable speed range above a predetermined speed depending upon varying intake manifold pressure.

4. In a transmission for motor vehicles, a power shaft, a driven shaft, a tail shaft, a multiple ratio gearing adapted to drivingly connect said power shaft and said driven shaft, devices operative to select different ratio drives through the gearing, shiftable selector mechanism including positive coupling means engagea-ble to effect forward or reverse drive from the driven shaft to the tail shaft, a brake device for holding the driven shaft stationary, a shift member operable by the driver for conditioning said mechanism for forward or reverse drive, a pressure fluid system connected to apply said devices, and valve means in the system and-operable by the member when in neutral position to allow fluid flow to thebrake device and to shut off fluid flow to the other devices, and when the member is in forward or reverse position to shut off fluid flow to the brake device and to permit fluid flow to the other devices.

5. In a transmission for motor vehicles, a power shaft, a driven shaft, planetary gearing adapted to connect said shafts in drive relation, fluid operable devices for selectively conditioning the gearing to drive inone of a plurality of gear ratios, a tail shaft, coupling means shiftable to connect said driven shaft and said tail shaft in relation for forward or reverse drive or neutral, a fluid operable brake device for the driven shaft, a pressure fluid system leading to said devices and the brake device, a sleeve valve in the system leading to the brake device, a shift rail carrying a fork for operating the clutch means, spring means operable by the sleeve valve to actuate the shift rail, and driver operated mechanism for shifting said sleeve valve, said sleeve valve having ports opening the fluid system to the brake device when in neutral position and closing the duid system to the brake device when in forward or reverse positions.

6. In a transmission for motor vehicles, a power shaft, a driven shaft. planetary gearing adapted to connect said shafts in drive relation, a tail shaft. coupling means shiftable to connect said driven shaft and said tail shaft in relation for forward or reverse drive or neutral, a fluid operable brake device for the driven shaft, a pressure fluid system leading to said brake device, a sleeve valve in the system leading to the driven shaft brake device, said sleeve having an internal groove comprised of a narrow inlet section and a wide outlet section, a shift rail carrying a fork for shifting the clutch means, spring means operable by the sleeve valve to actuate the shift rail, an arm engaging said sleeve valve, and driver operable mechanism for actuating said arm, said sleeve valve groove being open to allow fluid flow to the brake device when in neutral position and to shut off fluid flow to the brake device when in forward or reverse positions, the wide section of the groove venting uid in the brake device when fluid flow in the system is cut off by the sleeve valve.

'1. In a transmission for motor vehicles, a power shaft, a driven shaft, planetary gearing including a carrier adapted to connect said shafts in drive relation. a tail shaft, mechanism including coupling means shiftable to connect said driven shaft and said tail shaft in relation for forward or reverse drive or neutral, a fluid operable brake device for the carrier. a fluid operable brake device for the driven shaft, a pressure fluid system leading to said brake devices, a shift rail having a fork for-actuating the clutch means and valve means for controlling the fluid system to cut off flow to the carrier brake device in neutral position and to open the fluid system to the carrier brake device in forward or reverse drive positions, a sleeve valve around the rail having an internal groove controlling fluid flow in the system leading to the driven shaft brake device, spring means operable by the sleeve valve for shifting said rail, and driver operable means for shifting said sleeve valve, said sleeve valve groove opening the system to the driven shaft brake device when in neutral position and closing the system to the drive shaft brake device when in forward or reverse drive positions.

8. In a transmission for motor vehicles having a power shaft, a driven shaft, planetary gearing including a carrier adapted to drivingly connect the shafts, a fluid engageable brake device for preventing rotation of the carrier, a pressure uid system leading to the brake device having a flow control valve therein, actuator means for the brake device comprising nested pistons having relative movement axially, passage means from the exterior of the outer piston to the interior of the inner piston, vent means through the inner piston, and a valve controlling flow through said passage means and carried by the outer piston means.

9. In a transmission having a brake device operable to condition gearing in driving relation between shafts, control means for the brake device comprising a casing, two chambers in the casing connected by two passages. a control valve in one chamber, a pressure fluid system connected with the valve chamber, a pair of telescoped actuator pistons in the other chamber, the outer piston having a flange between the two passages leading to the actuator chamber and a port open to the interior of the inner piston, means limiting atomes relative axial movement of the inner piston in the outer piston, a spring acting to position the pistons in extended relation axially, a valve in the pistons for controlling fluid flow through the port in the outer piston, spring means in the inner piston bearing against and normally closing said valve. said valve being exposed to pressure fluid at the end of the outer piston, and mechanism operable by the inner piston for engaging or releasing said brake device, the control valve being operable to alternately open and close the two passages connecting the chambers.

10. In a transmission for motor vehicles driven by an engine. a power shaft driven by the engine. a driven shaft, planetary gearing adapted to drivingly connect said shafts and having a carrier, a reaction member, a brake device for the reaction member, an overrunning brake between the carrier and the reaction member, a clutch device for connecting the power shaft to the carrier, a pressure fluid system for applying the brake device and the clutch device, a normally open valve in the system controlling fluid flow to the brake device, fluid pressure operated means for holding the brake valve open, a speed inuenced valve in the system controlling uid flow to the clutch device, and means connecting the portion of the system between the clutch and clutch control valve with the said fluid pressure operated means whereby fluid pressure will hold the brake control valve open while the clutch control valve is open.

11. In a transmission for motor vehicles driven driven by an engine having an intake manifold, a power shaft driven by the engine. a driven shaft. planetary gearing adapted to drivingly connect said shafts and having a carrier, a reaction member, a brake device for the reaction member, an overrunning brake between the carrier and the reaction member, a clutch device for connecting the power shaft to the carrier, a pressure fluid system for applying the brake device and the clutch device, a normally open valve in the system controlling uid flow to the brake device, fluid pressure operated means for holding the brake valve open, a conduit connecting the manifold with the brake device control valve whereby manifold pressure when the engine is idling will close the valve, and means connecting the portion of the system between the clutch device and the clutch control valve with the said fluid pressure operated means whereby fluid pressure will hold the brake control valve open while the clutch control valve is open and the engine is idling.

12. In a transmission for motor vehicles driven by an engine having an intake manifold, a power shaft driven by the engine, a driven shaft, planetary gearing adapted to drivingly connect said shafts and having a carrier, a reaction member, an overrunning brake between the carrier and the reaction member, 'a brake device for holding the reaction member stationary to effect geared drive through the planetary gearing. a clutch device for connecting the power shaft to the carrier, a pressure fluid system for applying the brake device and the clutch device, normally open valve means in the system controlling fluid flow to the brake device, fluid pressure operated means integral with the brake valve for holding the brake valve means open, a conduit connecting the manifold with the valve means whereby manifold pressure will close the valve means while the engine is idling, a speed influenced valve in the system controlling fluid flow to the clutch,

and means connecting the portion of the system between the clutch control valve and the clutch device with the said uid pressure operated means whereby iiuid pressure against the said iiuid pressure operated means will hold the brake valve means open to apply the brake device while the clutch control valve is open and the engine is idling.

13. In a transmission for motor vehicles having a power shaft. a driven shaft, planetary gearing including a carrier adapted to drivingly connect the shafts, a fluid operable brake device for the carrier engageable to establish a reduci tion drive through the gearing, a iiuid operable clutch device for connecting the power shaft to the carrier. a pressure fluid system leading to said devices, a valve sleeve traversing the system having ports therein, a hollow valve member open at one end and having two positions to selectively control fluid flow through the sleeve ports to the devices, spring means normally positioning the valve member to connect the system with the clutch device, a solenoid effective when energized to position the valve member to connect the system with the brake device, said hollow valve member having a vent port registering with the brake device ports when the valve is open to the clutch device, electric circuit means connected with the solenoid, and a driver operable switch for controlling the circuit.

14. In a transmission for motor vehicles, a power shaft, a driven shaft, planetary gearing including a carrier adapted to drivingly connect said shafts, a fluid operable one-way brake device for engaging the carrier to establish reduced geared drive through the gearing, a uid operable clutch device for the gearing engageable to.

drivingly connect the carrier to the power shaft to establish a higher speed drive, a fluid system connected to the devices, three valves in the systern, one of the valves being normally open to connect the system to the brake device, the second valve being normally open to the clutch device, and the third valve controlling flow to the other two valves, and means responsive to engine operating conditions and vehicle speed below a predetermined value for closing the third valve.

l5. In a transmission for motor vehicles. a power shaft, a driven shaft, planetary gearing including a carrier adapted to drivingly connect said shafts, a iiuid operable one-way brake device for engaging the carrier to establish reduced geared drive through the gearing. a fluid operable clutch device for the gearing engageable to drivingly connect the carrier to the power shaft to establish a higher speed drive. a fluid system connected to the devices, three valves in the system, one of the valves being normally open to connect the system to the brake device, the second valve being normally open to the clutch device, and the third valve controlling flow to the other two valves and normaly open through one of said two valves to the clutch device, and means responsive to engine operating conditions and vehicle speed below a predetermined value for closing the third valve.

16. In a transmission for motor vehicles driven byA an engine having a fuel intake manifold, a. power shaft, a driven shaft, planetary gearing including a carrier adapted to drivingly connect said shafts, a iiuid operable one-way brake device for engaging the carrier to establish reduced geared drive through the gearing, a fluid operable clutch device for the gearing engageable to drivingly connect the carrier to the power shaft to establish a higher speed drive, a fluid I system connected to the devices. three valves in the system, one of the valves being normally open to connect the system to the brake device, a connection between the manifold and brake device valve whereby pressure in the manifold while the engine is idling will move the valve to closed position, the second valve being normally open to the clutch device, and the third valve controlling ow to the other valves and normally open to the clutch device, and means responsive to engine operating conditions and vehicle speed below a predetermined value for closing the third valve.

17. In a transmission for motor vehicles, a power shaft, a driven shaft, planetary gearing including a carrier adapted to drivingly connect said shafts, a iiuid operable one-way brake device for engaging the carrier to establish reduced geared drive through the gearing, a fluid operable clutch device for the gearing engageable to drivingly connect the carrier to the power shaft to establish a higher speed drive, a fluid system connected to the devices, three valves in the system, one of the valves being normally open to connect the system to the brake device. the second valve being normally open to the clutch device, and the third valve controlling iiow to the other valves and normally open to the clutch device, electrically energized means for closing the third valve, and switch means responsive to engine operating conditions and vehicle speed below predetermined values for closing the electrically energized means.

18. In a transmission for motor vehicles, a power shaft, a driven shaft, planetary gearing including a carrier adapted to. drivingly connect said shafts, a fluid operable one-way brake device for engaging the carrier to establish reduced geared drive through the gearing, a fluid operable clutch device for the gearing engageable to drivingly connect the carrier to the power shaft to establish a higher speed drive. a uid system connected to the devices, three valves in the system, one of the valves being normally open to connect the system to the brake device, the second valve being normally open to the clutch device, and the third valve controlling flow to the other valves and normally open to the clutch device. electrically energized means for closing the third valve, switch means responsive to engine operating conditions and vehicle speed below a. predetermined Value for closing the electrically energized means, and driver controlled electrically energized means for shifting the second valve into position closing off fluid flow to the clutch device.

19. In a transmission for motor vehicles. a power shaft, a driven shaft, planetary gearing including a carrier adapted to drivingly connect said shafts, a fluid operable one-way brake device for engaging the carrier to establish reduced geared drive through the gearing, a fluid operable clutch device for the gearing engageable to drivingly connect the carrier to the power shaft to establish a higher speed drive. a fluid system connected to the devices, three valves in the system, one of the valves being normally open to connect the system to the brake device, the second valve being normally open to the clutch device, and the third valve controlling iiow to the other valves and normally open to the clutch device, electrically energized means for closing the third valve, switch means responsive to engine operating conditions and vehicle speed below 19 predetermined values for energizing said electrically energized means, and driver operated means for controlling the electrically energized means.

20. In a transmission mechanism for motor vehicles, a power shaft, a driven shaft, planetary gearing including a gear carrier connected between said shafts, a brake device for engaging said carrier to establish a geared drive between said shafts. a fluid pressure system. and means operated by said system for engaging said brake device with progressively increasing eect to thereby obtain a soft application of said brake device, said means including a piston, means for trapping fluid on one side ofthe piston to oppose movement of the piston in the direction of said side, and means for releasing the trapped fluid.

2i. In a transmission mechanism for motor vehicles, a power shaft, a driven shaft, planetary gearing including a gear carrier connected between said shafts, a brake device for engaging said carrier to establish a geared drive between said shafts, a fluid pressure system, and means operated by said system for engaging said brake device with progressively increasing effect to thereby obtain a soft application of said brake device, said means including spring controlled nested pistons and valve means, said valve means including means for trapping fluid on one side of one of said pistons to oppose motion of the fluid in a brake applying direction and other means for releasing the trapped fluid to permit movement of the piston in a brake applying direction.

22. In a transmission mechanism for motor vehicles, a power shaft, a driven shaft, planetary gearing including a gear carrier connected between said shafts, a brake device for engaging said carrier to establish a geared drive between said shafts a fluid pressure system, and means operated by said system for engaging said brake device with varying pressure. said means comprising a piston, a control valve in the system, conduits connecting the valve to the piston, one conduit conducting pressure fluid to one side of the piston to apply the brake and the other conducting pressure fluid to the other side to tend to release the brake, a second piston nested in the first piston, both said pistons having passageways for conducting fluid from the said other side of the first-mentioned piston, resilient means acting on the second piston in opposition to the fluid pressure on the second piston and holding the passageways in the pistons out of register whereby to trap uid under pressure on the said one side of the piston, said resilient means being yieldable under fluid pressure acting upon the second piston to cause the passageways to become aligned thereby to conduct the trapped fluid from the said one side of the piston to release the piston for movement in a direction to engage the brake, and means for venting the aligned passageways, said valve being adapted to apply fluid under pressure through one of said conduits to the said one side of the piston and then to close the said one conduit and apply fluid under pressure to the other side of the piston through another of said conduits.

23. In a transmission for motor vehicles. a power shaft, a driven shaft, planetary gearing including a gear carrier connected between said shafts, a brake device for engaging said carrier to establish a geared drive between said shafts, a fluid pressure system, and means operated by 'said system for engaging said brake device, said means comprising a pair of nested pistons, means for introducing fluid under pressure to one side of one piston, means for introducing fluid under pressure to the other side of said piston, and means in the other of said pair of pistons for trapping and then venting the fluid introduced to said one side of said one piston, whereby to retard the movement of the said one piston when fluid under pressure is introduced to the said other side thereof.

24. A transmission as described in claim 23, the means in the other of said pistons for trapping and then venting the fluid comprising a spring acting to move the said other of said pistons in one direction, and uid under pressure 'acting in opposition to the spring, both said pistons having passages which when aligned allow the trapped fluid to escape.

25. In a transmission for motor vehicles, a power shaft, a driven shaft and a tail shaft, change speed gearing adapted to connect said power and driven shafts, pressure fluid operated devices controlling the operation-of said gearing for different ratio drives, shiftable selector mechanism including positive clutch means having teeth engageable to effect forward or reverse drive from the driven shaft to the tail shaft, a synchronizer device for holding the driven shaft stationary, a driver operated shift member for conditioning said mechanism for forward or reverse drive. a fluid pressure system connected to operate said devices, and valve means operated by said shift member and having a porting arrangement which permits fiuid flow to the synchronizer device when the member is in neutral position and shuts off fluid flow to said synchronizer device and vent said device to the atmosphere after the teeth of said clutch means have been shifted into abutment when the member is shifted to forward or reverse position.

26. In a transmission for motor vehicles, a power shaft, a driven shaft and a tail shaft. planetary gearing including a carrier adapted to connect said power and driven shafts, a brake device for the carrier, shiftable selector mechanism including positive clutch means having teeth engageable to effect forward or reverse drive from the driven shaft to the tail shaft. a synchronizer device for holding the driven shaft stationary, a driver operated shift member conditioning said mechanism for forward or reverse drive, a fluid pressure system for operating said synchronizer device and said brake device, and valve means operated by said member and having ports so arranged as to permit fluid flow to the synchroniser device when the member is in neutral position and shut-oil fluid flow to said device when the member is shifted to forward or reverse position and vent said synchronizer device to the atmosphere after the teeth of said clutch means have been shifted into engagement and to permit fluid flow to said brake device to apply the same after the member is shifted to forward or reverse position.

27. In a transmission for motor vehicles, a power shaft, a driven shaft, planetary gearing including a carrier adapted to drivingly connect the shafts, a fluid operated brake device for preventing rotation of the carrier to establish geared drive, operated means for said brake device, a fluid operated clutch device for the gearing engageable to establish a higher speed drive, a fluid system including valve means for controlling operation of said clutch device, fluid passage means leading to and from said brake device operating means. and a valve device for controlling the engagement and release of said brake device, said valve device having a vent and comprising a valve member slidable in a chamber to open and close said passages and vent, an element slidable in said chamber and a spring normally holding said element out of relationship with said vent, said Aelement being moved into such relationship under the control of said clutch control valve means so that is cooperates with the first-mentioned valve member to restrict fluid iiow through said vent and delay full release of the brake device until the clutch device is suf ciently engaged to take up the motor torque upon shift-up from geared. drive to the higher speed drive.

FOREST R. MCFARLAND.

REFERENCES CITED The following references are of record in the le of this patent:

Number Number 22 UNITED STATES PATENTS Name Date Leoni July 23, 1935 Duilleld Mar. 23, 193'? Sinclair Dec. 26, 1939 Thompson Mar. 1.2, 1940 Cotterman Nov. 12, 1940 Dolza May 12, 1942 Cotterman May 18, 1943 McFarland July 20, 1943 Nutt et al Oct. 26, 1943 Duflleld Aug. 8, 1944 Voytech April 2, 1946 Hale June 18, 1946 La Brie Sept. 10, 1946 FOREIGN PATENTS Country Date Great Britain Sept. 3. 1931 

